Anomalous Behaviors of Visible Luminescence from Graphene

Sung Kim,†,# Sung Won Hwang,‡,# Min-Kook Kim,§ Dong Yeol Shin,† Dong Hee Shin,† Chang Oh Kim,† Seung Bum Yang,† Jae Hee Park,† Euyheon Hwang,† Suk-Ho Choi,†,* Geunwoo Ko,‡ Sunghyun Sim,‡ Cheolsoo Sone,‡ Hyoung Joon Choi,§ Sukang Bae,^ and Byung Hee Hong^

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Anomalous Behaviors of Visible Luminescence from Graphene Quantum Dots: Interplay between Size and Shape †

Department of Applied Physics, Kyung Hee University, Yongin 446-701, Korea, ‡Advanced Development Department, Samsung Electronics Co., Ltd, Yongin 446-711, Korea, Department of Physics and IPAP, Yonsei University, Seoul 120-749, Korea, and ^Department of Chemistry, SKKU Advanced Institute of Nanotechnology, Sungkyunkwan University, Suwon 440-746, Korea. #These authors contributed equally to this work. §

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ecently, the quantum confinement effect (QCE) at a nanometer scale as in graphene quantum dots (GQDs) and graphene nanoribbons (GNRs) has attracted strong attention as one of the central issues in graphene-based electronics1
4 because they provide the opportunity to explore novel structural, optical, and electrical phenomena not obtainable in other materials. Having a controllable nanometersized graphene system that can produce tunable light in the visible range is highly desirable for optoelectronic device applications of graphene. Therefore, it is essential to be able to engineer the bandgap of GQDs or GNRs by varying their size or width, respectively. Graphene is a single atomic layer of graphite with an infinite exciton Bohr radius due to its linear energy dispersion relation of the charge carriers,2,5 resulting in QCE for graphene of any finite size.1,4 The energy gap of GQDs falls off as approximately 1/L,4,6 where L is the average size of GQDs. The bandgap has been observed up to ∼0.4 eV in GNRs,4,7 while it can be controlled up to ∼3 eV in GQDs by reducing their size,6,8,9 more promising for photonic nanodevices. Near-ultraviolet-to-blue photoluminescence (PL) observed from GQDs fabricated through various processes8,10,11 has been attributed to the recombination of electron
hole pairs in quantum-confined GQDs. However, the optical transitions for PL are allowed to be up to ∼3 eV in GQDs larger than ∼3 nm in size8,11,12 and their size dependence is unclear,13 not consistent with theoretically predicted bandgap energies of GQDs that well follow QCE but are not beyond 1 eV in these sizes.6,9 Here, we report novel behaviors of absorption and KIM ET AL.

ABSTRACT

For the application of graphene quantum dots (GQDs) to optoelectronic nanodevices, it is of critical importance to understand the mechanisms which result in novel phenomena of their light absorption/emission. Here, we present size-dependent shape/edge-state variations of GQDs and visible photoluminescence (PL) showing anomalous size dependences. With varying the average size (da) of GQDs from 5 to 35 nm, the peak energy of the absorption spectra monotonically decreases, while that of the visible PL spectra unusually shows nonmonotonic behaviors having a minimum at da = ∼17 nm. The PL behaviors can be attributed to the novel feature of GQDs, that is, the circular-to-polygonal-shape and corresponding edge-state variations of GQDs at da = ∼17 nm as the GQD size increases, as demonstrated by highresolution transmission electron microscopy. KEYWORDS: graphene . quantum dot . size . shape . edge . photoluminescence

nonmonotonic visible PL of GQDs in the size range from 5 to 35 nm, and show that the anomalous PL phenomena can be explained by the size-dependent shape and corresponding edge-state variations of GQDs, as confirmed by high-resolution transmission electron microscopy (HRTEM). RESULTS AND DISCUSSION

Received for review June 28, 2012 and accepted August 10, 2012. Published online 10.1021/nn302878r

We prepared GQDs by hydrothermal (chemical) cutting8 of graphene sheets that VOL. XXX

* Address correspondence to [email protected].

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Figure 1. (a) A typical distribution of GQDs with an average size of 12 nm. (b) Definition of the average size: half of (width þ length) of a GQD. (c) A magnified HRTEM image showing arrangements of carbon atoms in a typical circular GQD, which shows an average C
C bond length is 1.44 Å. (d) A magnified HRTEM image showing the edge of a typical circular GQD is of zigzag type.

of a GQD, as shown in Figure 1b. It is possible to see the hexagonal unit cell of GQDs in higher-resolved HRTEM images, as shown for a typical circular GQD in Figure 1c, demonstrating that the GQDs consist of graphene. The average C
C bond length is estimated to be about 1.44 Å, very close to that in graphite.16 Figure 1d shows that the edge of a typical circular GQD is of zigzag type. The HRTEM images were analyzed for individual GQDs to classify their major shapes at each d. Figure 2 shows the most common shapes for a given size of GQDs in percentage (p) (see also Supporting Information Figure S1). Average sizes of GQDs estimated from the HRTEM images at each d are indicated in parentheses at the bottom of Figure 2. Circular and elliptical GQDs of ∼5 and ∼12 nm average sizes are produced at d = 5 and 10 nm, respectively. In these samples, circular GQDs occupy more than 50% of the total number of GQDs at each d. At d = 15 nm, circular GQDs disappear and only elliptical GQDs are seen with ∼1/3 of them deformed. At d = 20 nm, most GQDs are hexagon-shaped, but ∼1/4 of them are deformed with curved sides. At d = 25 nm, the major portion of GQDs are still hexagon-shaped with minor irregularshaped GQDs. At d = 35 nm, most QDs are shaped as parallelogram-type rectangles with rounded vertices. Recently, it has been known that the equilibrium shape of the GQDs synthesized by transformation of C60 can be tailored by optimizing the annealing temperature and the density of the carbon clusters.17

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were obtained by thermal deoxidization of graphene oxide sheets made from natural graphite powder by a modified Hummers method.14,15 GQDs at a particular size (d) were obtained by filtering and dialysis processes. HRTEM images were obtained for six kinds of samples with d from 5 to 35 nm. Figure 1a shows a typical distribution of GQDs at d = 10 nm (average size = 12 nm). Average size (da) is defined as half of (width þ length)

Figure 2. HRTEM images of GQDs for their major shapes and corresponding populations (p) with increasing average size of GQDs. Here, the dotted line indicates the region of a GQD and p is defined as the ratio of number of GQDs with a major shape at each average size. Average sizes (da) of GQDs estimated from the HRTEM images at each d are indicated in the parentheses at the bottom of Figure 2. The connected arrows indicate the range of the average size in which GQDs with particular major shapes are found. KIM ET AL.

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ARTICLE Figure 3. A HRTEM image showing mixed edges of zigzag and armchair at four different edge positions (1
4) of a typical GQD (a) with partially curved and linear regions at the edge. Red and blue lines show zigzag and armchair edges, respectively, in the magnified HRTEM images (a1
a4) corresponding to the four edge positions. Zigzag and armchair edges are mixed in curved regions, but the armchair edge is dominant in linear regions. The scale bars in a1
a4 are all 1 nm.

The detailed analysis of HRTEM images for GQDs shows that the periphery of GQDs consists of mixed zigzag and armchair edges. Figure 3 shows the edge states at four different edge positions (1
4) of a typical GQD (a) with partially curved and linear regions at the edge. Red and blue lines show zigzag and armchair edges, respectively, in the magnified HRTEM images (a1
a4) corresponding to the four edge positions. We find that both edges are mixed in curved periphery while the armchair edge appears more frequently in straight periphery. As a consequence, it appears that circular/elliptical GQDs consist of both edges, but polygonal GQDs consist mostly of armchair edge. Atomic force microscopy (AFM) images/height profiles of GQDs show that the average thickness of GQDs increases with increasing their size (see Supporting Information Figure S2). For da e 17 nm, the GQDs consist mostly of 1
3 graphene layers, but for da g 22 nm, the GQDs comprising more than 5 graphene layers are also found. These results are consistent with the electron energy loss spectroscopy (EELS) results (see Supporting Information, Figure S3). There have been several reports on the absorption spectra of graphene-related materials. For graphene oxide sheets, a typical absorption peak has been observed at 5.4 eV,8 corresponding to the π f π* transition at M point of the Brillouin zone. It has been theoretically expected that with/without exciton effects, the interband transitions of a graphene sheet form a prominent absorption peak at 4.55 and 5.15 eV, respectively.18 Blue-luminescent GQDs in water have been shown to exhibit absorption spectrum peaked at 3.9 eV.8 For the GQDs in this work, however, the absorption peaks are observed at even larger energies. KIM ET AL.

Figure 4. Absorption spectra for three typical GQDs of 12, 17, and 22 nm average sizes dispersed in DI water and a graphene sheet. Filled circular dots indicate the peak positions of the absorption spectra for GQDs. Inset: absorption peak energy as a function of average GQD size.

Figure 4 shows absorption spectra of different-size GQDs dispersed in deionized (DI) water and a graphene sheet (see also Supporting Information Figure S4). The absorption peak of GQDs is blue-shifted with respect to that of a graphene sheet (270 nm, 4.6 eV), and is sequentially shifted to higher energies by reducing their size, consistent with the QCE. The inset shows the peak energy as a function of da. As da increases from 5 to 35 nm, the peak energy almost monotonically decreases from ∼6.2 to ∼4.6 eV, very close to that of a graphene sheet. Figure 5a shows size-dependent PL spectra excited at 325 nm for GQDs in DI water. The peak energy and the shape of the PL spectra are strongly dependent on the size of GQDs. A sharp PL peak at 365 nm originates from DI water19 (see Supporting Information Figure VOL. XXX

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ARTICLE Figure 5. (a) Size-dependent PL spectra excited at 325 nm for GQDs of 5
35 nm average sizes in DI water. Inset: different colors of luminescence from GQDs depending on their average size for three typical GQDs of 12, 17, and 22 nm average sizes. (b) Dependence of PL peak shifts on the excitation wavelength from 300 to 470 nm for GQDs of 5
35 nm average sizes.

S5). The inset of Figure 5a shows different colors of luminescence depending on the size of GQDs. Especially for da = 17 and 22 nm, the PL spectra are resolved in two PL bands, irrespective of the excitation wavelength, possibly resulting from combination of different-size/shape GQDs, as shown in Figure 2. As the excitation wavelength is changed from 300 to 470 nm, the PL peak sequentially shifts to longer wavelengths (see also Supporting Information Figure S5). This trend is similar for all GQD sizes. Figure 5b summarizes excitation-wavelength-dependent PL peak shifts for various-size GQDs. All PL spectra show similar sizedependent peak shifts, almost irrespective of excitation wavelength except 470 nm. The PL peak energy decreases as da increases up to ∼17 nm, consistent with the QCE. However, for da > ∼17 nm the PL peak energy increases with increasing da; in other words, the QCE no longer holds. This unusual size dependence of luminescence is similar to what was found in reconstructed Si nanoparticles.20,21 It has been reported that after the hydrothermal treatment in the fabrication processes of GQDs, several oxygen-functional groups (OFGs) could remain at the edges of GQDs, thereby possibly affecting the PL behaviors of GQDs.8,13 We studied the effect of the OFGs such as C
O, CdO, and COOH on the structure of GQDs by X-ray photoelectron spectroscopy (XPS) for various-size GQDs. The XPS peaks resolved based on the previous report13 did not give any evidence that the population of the OFGs relative to that of the CdC bond depends on the size of GQDs (see Supporting Information Figure S6). This suggests that despite the presence of the OFGs in GQDs, they do not give any size-dependent effect on the structures of GQDs, resulting in a negligible effect on the size-dependent PL behaviors of GQDs. As shown in Figures 2 and 3, for da e ∼17 nm the majority of GQDs is of circular/elliptical shape with mixed edges of zigzag and armchair, but for da > ∼17 nm they are of polygonal shape mostly with armchair edge. The PL peak energy decreases as da KIM ET AL.

increases as long as GQDs keep their shape circular/ elliptical for da e ∼17 nm, but when the shape of GQDs varies into polygons for da > ∼17 nm, the PL peak energy increases with increasing da. These results suggest that the anomalous size dependence of the PL peak above da = ∼17 nm can be attributed to the novel feature of GQDs, that is, the circular-topolygonal-shape and corresponding edge-state variations of GQDs at da = ∼17 nm as the GQD size increases. Our calculations also showed that the averaged PL energy could increase with increasing da (contradictory to QCE) due to the change of the shape or the edge type at larger da. (see Supporting Information Figure S7) Several theoretical studies have shown that the bandgap energies of GQDs in the size range of 5
35 nm are not beyond ∼1.0 eV,6,9 which cannot explain why the experimental PL peak energies of GQDs reach ∼3 eV, as shown in Figure 5 and as seen in previous reports.8,11,12 The visible PL found in a graphene sheet has been explained by minimization of thermalization due to electron
phonon scattering by using ultrafast high-power light source22
24 or by formation of excited-state relaxation channel resulting in inelastic light scattering by electric doping.25 Our study shows that such light-emission phenomena can also be explored in GQDs because electronic transitions can be modified in nanometer-sized systems to produce strong visible PL emissions in a controlled fashion, that is, by size and size-dependent shape/ edge-state variations of GQDs. The high-energy PL of GQDs is especially efficient due to the unique properties of graphene: fast carrier
carrier scattering dominating over electron
phonon scattering, predicted by theory,26,27 and confirmed by ultrafast dynamics experiments.28,29 This facilitates direct recombination of excited e
h pairs producing such high-energy PL before thermalization of the carriers with the lattice. The high Coulomb scattering rate of graphene,30
32 which is attributed to the strongly reduced dielectric screening in the two-dimensional structure, is also VOL. XXX

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EXPERIMENTAL SECTION

REFERENCES AND NOTES

CONCLUSION

GQDs were fabricated by the following processes. Graphene oxide (GO) sheets were obtained from natural graphite powder by a modified Hummers method.14,15 The GO sheets were subsequently deoxidized in a tube furnace at 250 C for 2 h under Ar ambient to prepare reduced graphene oxide powder, 0.05 g of which were then oxidized in concentrated 10-mL H2SO4 and 30-mL HNO3 for 20 h under mild ultrasonication. The mixture was then diluted with 250-mL DI water and filtered through a 200-nm nanoporous membrane to remove the acids. The size-reduced/purified 0.2-g GO powder was redispersed in 40-mL DI water and the pH was tuned to 8 with NaOH. The suspension was transferred to a nitrogen-ambient furnace and heated at 250 C for 10 h. After cooling to room temperature, the resulting powder was redispersed in 40-mL DI water for 2 h under ultrasonication. Then, by filtering the resulting suspension through a 200-nm nanoporous membrane, a brown filter solution was separated. Since the colloidal solution still contained some large graphene nanoparticles (